JP4267629B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic device, and more particularly to an electronic device including a heating element such as a semiconductor and a cooling device for cooling the heating element.

  Recently, information processing speed has been greatly improved in electronic devices such as personal computers, and accordingly, the amount of heat generated by semiconductor elements such as CPUs has also increased. For this reason, forced cooling has become indispensable in order to maintain the performance of these semiconductor elements.

  In recent years, not only the CPU but also the heat generation of high-speed signal processing semiconductor elements such as graphic controllers that perform image processing has increased, and a plurality of semiconductor elements that require forced cooling in a single housing have been added. Increasing forms of electronic devices are included.

  Conventionally, various forms have been adopted for forced cooling methods such as CPU. Among these, there is a form in which heat of a heat receiving body thermally connected to a heat generating body (CPU or the like) is transferred to a heat radiating body with a heat pipe and the heat radiating body is forcibly air-cooled with a fan or the like.

  Patent document 1 is disclosing one of the techniques which concern on this form. An electronic device disclosed in Patent Document 1 is, for example, a notebook personal computer, and an electronic device main body and a panel unit are connected to each other through a hinge unit so as to be freely opened and closed. The electronic device main body stores components in a thin casing, and a heating element such as a CPU and a cooling device are stored in the casing. Ventilation holes are provided in the side wall of the housing, and the cooling device is disposed in the vicinity of the ventilation holes. Cooling air from the cooling device is discharged to the outside of the housing through the ventilation holes.

  The cooling device includes a radiator, a cooling fan, a heat pipe, and a heat receiver. A heat receiving body at one end of the heat pipe is thermally connected to a heat generating body (CPU). The other end of the heat pipe is thermally connected to the heat radiating body, and the heat of the heat generating body (CPU) is transferred through the heat receiving body to the heat radiating body.

The heat radiating body includes a large number of fins, and heat exchange is performed between the fins and the cooling air generated by the cooling fan. The received cooling air is discharged to the outside through the ventilation holes.
JP 2003-97892 A

  By the way, in the conventional electronic device configured as described above, not all of the received cooling air is discharged outside the housing, but a part of it flows back into the housing. There is.

  In order to efficiently discharge the received cooling air to the outside, the cooling fin and the heat radiating body may be brought as close to the ventilation hole (side wall) as possible. However, it is not possible to completely eliminate the gap formed between the side wall and the radiator from the viewpoint of ease of work when incorporating the cooling fin and the radiator into the housing, restrictions on the arrangement of the fixing members, etc. Have difficulty.

  For this reason, a part of the received cooling air hits the partition wall of the ventilation hole, passes through the gap, and returns to the inside of the housing as the circulating cooling air.

  As a result, the internal temperature of the housing rises, the temperature of the cooling air itself generated by the cooling fan rises, and the cooling performance for the heating element is lowered. For this reason, in order to ensure the required cooling performance, the cooling fan and the heat radiating body may have to be enlarged.

  Moreover, the temperature rise inside the housing may adversely affect other semiconductor elements and electronic components that are not required until forced air cooling.

  The present invention has been made in view of the above circumstances, and can reduce the circulation of the received cooling air into the housing, improve the cooling efficiency, and reduce the temperature rise inside the housing. The purpose is to provide.

In order to solve the above-described problems, an electronic device according to the present invention includes, as described in claim 1, a housing having a side wall provided with ventilation holes, a heating element housed in the housing, and the ventilation. A radiator disposed close to the hole, a heat receiver thermally connected to the heat generator, one end thermally connected to the heat receiver, and the other end thermally connected to the radiator A gap between the heat transfer means, the fan that is disposed in proximity to the heat radiating member and generates cooling air toward the heat radiating member, and the side wall provided with the heat radiating member and the ventilation hole And a closing member configured separately from a fan case that houses the fan , the heat dissipating member has a plurality of plate fins, and the other end of the heat transfer means The closing member is a fan case that houses the fan. Are formed so as to further close the gap between the heat sink and the two side blocking plates that close both sides of the gap, and an upper blocking plate that closes the gap. The heat transfer member is a heat pipe, and the side block plate is provided with a notch for avoiding mechanical interference with the heat pipe, and the side block plate has an edge portion, It is connected to at least one of the bottom wall of the housing and the side wall provided with the ventilation hole, and is integrally formed on the rib structure, and a recess is formed in the bottom wall of the housing, The fan and the heat radiating body are placed in contact with each other.

  According to the electronic device of the present invention, it is possible to reduce the recirculation of the received cooling air into the housing, improve the cooling efficiency, and reduce the temperature rise inside the housing.

  Embodiments of an electronic apparatus according to the present invention will be described with reference to the accompanying drawings.

(1) First Embodiment FIG. 1 is a perspective view showing an example of the appearance of an electronic apparatus 1 according to an embodiment of the present invention, for example, a notebook personal computer.

  In the electronic device 1, as shown in FIG. 1, the electronic device main body 3 and the panel unit 2 are coupled via a hinge unit 5 so as to be freely opened and closed. The panel unit 2 is provided with a liquid crystal panel 6 for displaying various information and images.

  The electronic device main body 3 stores various components in a thin casing 7, and a heating element 50 such as a CPU and a graphic controller and a cooling device 20 are stored in the casing 7. The housing 7 includes a side wall 8, a side wall 9, a front wall 10, a bottom wall 11, an upper wall 12, and a rear wall 13.

  The side wall 8 is provided with a plurality of ventilation holes 15, and the cooling device 20 is disposed in the vicinity of the ventilation holes 15. The heating element 50 is cooled by the cooling device 20, and the cooled cooling air received after cooling is discharged to the outside of the housing 7 through the ventilation holes 15.

  FIG. 2 is a plan view schematically showing the heating element 50, the cooling device 20, and the cooling structure around the cooling device 20.

  The cooling device 20 includes a cooling fan (fan) 21, a heat radiating body 40, a heat pipe (heat transfer means) 24, and a heat receiving body 25.

  The cooling fan 21 includes a rotating fan (fan) 22 that is rotationally driven by a motor (not shown), and a fan case 21 a that houses the rotating fan 22.

  The heat radiating body 40 is disposed adjacent to the fan case 21a so as to cover the fan opening 21b of the fan case 21a. The radiator 40 is composed of, for example, a large number of plate-like fins 41. The plate-like fins 41 are made of a metal having high thermal conductivity, such as aluminum or copper.

  The heat pipe 24 is a heat transfer element that can transfer heat at high speed, and its outer periphery is covered with a metal such as copper. One end 24 a of the heat pipe 24 is thermally connected to the heat receiving body 25. The heat receiving body 25 is formed of a metal having high heat conductivity such as copper, and is thermally connected to a heat generating body 50 such as a CPU.

  On the other hand, the other end 24 b of the heat pipe 24 penetrates the plate-like fin 41 of the heat radiating body 40 and is thermally connected to the plate-like fin 41.

  The side walls 8 are provided with a plurality of ventilation holes 15 for discharging the received cooling air 60 to the outside of the housing 7.

  The cooling fan 21 and the radiator 40 connected to the cooling fan 21 are disposed so as to face and close to the ventilation hole 15 in order to efficiently discharge the received cooling air 60 to the outside of the housing 7. There is a slight gap 70 between the radiator 40. From the viewpoint of ease of work when the cooling fan 21 and the radiator 40 are incorporated in the housing 7 and restrictions on the arrangement of fixing members for fixing these to the bottom wall 11, the side wall 8 and the radiator 40 This is because it is difficult to completely eliminate the gap 70 between them.

  Side block plates (blocking plates: blocking members) 30a and 30b and upper blocking plates (blocking plates: blocking members) 45 (see FIG. 3) provided on both sides in the longitudinal direction of the heat radiating body 40 are formed in the gap 70. Therefore, the received cooling air 60 is provided to prevent the cooling air 60 from flowing back to the housing 7. Due to the presence of the side blocking plates 30a and 30b and the upper blocking plate 45, the received cooling air 60 can be efficiently discharged to the outside of the housing 7 through the ventilation holes 15 without circulating to the inside of the housing 7. Is possible.

  FIG. 3 is a side view schematically showing the cooling device 20 and the cooling structure in the vicinity thereof.

  The cooling fan 21 and the heat radiating body 40 are arranged close to the bottom wall 11 side of the housing 7. The cooling air generated by the cooling fan 21 receives heat by exchanging heat with the plate fins 41 while passing through the gaps between the plate fins 41 of the radiator 40. The received cooling air 60 passes through the gap 70 and is discharged to the outside of the housing 7 through the ventilation hole 15 provided in the side wall 8.

  At this time, the gap 70 is closed by the side closing plates 30a, 30b (in FIG. 3, the side closing plate 30a is not visible because it is located on the opposite side) and the upper closing plate 45, so 7, almost all of the received cooling air 60 passes through the ventilation holes 15 and is discharged to the outside of the housing 7.

  The edge part which opposes the bottom wall 11 of the side obstruction | occlusion board 30a, 30b, and the edge part which opposes the side wall 8 are connected with at least one of the bottom wall 11 and the side wall 8, respectively, and are integrally formed in rib structure shape. You may do it. With such a structure, leakage of the cooling air 60 that has received heat from the gap 70 can be prevented more reliably. Further, the assembly work of the side closing plates 30a and 30b is simplified and the workability is improved.

  The side blocking plates 30a and 30b are provided with notches 36 as shown in FIG. This notch 36 is for avoiding mechanical interference between the heat pipe 24 penetrating the heat radiating body 40 and the side closing plates 30a, 30b. If there is a mechanical interference between the heat pipe 24 and the side blocking plates 30a and 30b, an unnecessary force is applied to the heat pipe 24, not only the deformation of the heat pipe 24 itself but also the one end 24a of the heat pipe 24. Stress is applied to the heat receiving body 25 and the heat generating body 50 that are bonded, and in some cases, bonding peeling may occur. Such a problem can be solved by the notch 36.

  The material of the side blocking plates 30a and 30b is not particularly limited, but is formed of the same kind of resin, lightweight alloy, or the like as the material of the housing 7.

  Since the upper closing plate 45 is placed on the heat radiating body 40, it does not need to have any particular strength, and can be formed of, for example, a thin resin film.

  According to the cooling device 20 and the cooling structure of the electronic device 1 according to the first embodiment, the casing 7 of the received cooling air 60 is provided by providing the closing plate in the gap 70 between the radiator 40 and the ventilation hole 15. It becomes possible to prevent the circulation to the inside, and to reduce the temperature rise inside the housing 7. As a result, the temperature of the cooling air itself generated by the cooling fan 21 is lowered and the cooling performance of the heating element 50 is improved as compared with the electronic device according to the prior art. For this reason, it becomes possible to ensure a required cooling performance with the small cooling device 20 compared with the conventional cooling device 20. Moreover, it contributes to the reduction in power consumption of the cooling device 20.

  Moreover, since the temperature rise inside the housing | casing 7 can be reduced, the influence by a heat | fever can be reduced also with respect to the semiconductor element and electronic component which do not require forced cooling.

(2) Second Embodiment FIG. 4 is a plan view schematically showing the cooling device 20 and the cooling structure of the electronic device 1 according to the second embodiment.

  The difference from the first embodiment is that it has two cooling systems. That is, as a cooling system for the first heating element 51, the first heat radiator 42 disposed close to the side wall 8, the first heat pipe 26 having the other end 26b thermally connected thereto, And a first heat receiving body 27 that is thermally connected to one end 26 a of one heat pipe 26.

  Similarly, as a cooling system for the second heating element 50, the second radiator 40 disposed between the first radiator 42 and the cooling fan 21, and the other end 24b are thermally connected thereto. A second heat pipe 24 and a second heat receiving body 25 thermally connected to one end 24a of the second heat pipe 24.

  Since each cooling system itself is the same as that described in the first embodiment, description thereof is omitted.

  In the electronic device cooling structure according to the second embodiment, the first gap 72 formed between the side wall 8 and the first radiator 42, the first radiator 42, and the second radiator 40. Two gaps of the second gap 71 are formed between the two.

  For this reason, the blocking plate according to the second embodiment has a structure capable of preventing the circulating flow of the cooled cooling air 60 received from these two gaps. Specifically, the side closing plates 31a and 31b and the upper closing plates 46 and 47 (see FIG. 5) constitute a closing plate.

  FIG. 5 is a side view schematically showing the cooling device 20 and the cooling structure of the electronic device 1 according to the second embodiment. In order to cover both the first gap 72 and the second gap 71, the side blocking plates 31a and 31b (in FIG. 5, the side blocking plate 31a is on the opposite side and is not visible) Compared to the embodiment, the shape is longer in the direction in which the cooling air flows. Further, two cutouts 38 and 37 are provided in the side blocking plates 31a and 31b in order to avoid mechanical interference with the first and second heat pipes 26 and 24.

  The upper closing plate includes two divided upper closing plates 46 and 47 corresponding to the two gaps 72 and 71. The two upper closing plates may be integrally formed as one upper closing plate.

  According to the cooling device 20 and the cooling structure of the electronic device according to the second embodiment, in addition to the effects of the first embodiment, a plurality of heating elements, for example, a CPU and a graphic controller can be cooled.

(3) Third Embodiment FIG. 6 is a perspective view showing a cooling device 20 and a cooling structure of an electronic device according to a third embodiment. In FIG. 6, the structure of the tip of the heat pipe extending from the heat radiating body is omitted.

  The third embodiment is similar to the second embodiment, but the difference is that one heating element is configured to be cooled by two heat pipes. Specifically, the second heat radiating body 40 is made to pass through the two heat pipes 24, 28, and the heat of one heating element is transferred by each of the two heat pipes 24, 28. .

  FIG. 7 is a perspective view illustrating the cooling system related to the second heat radiating body 40 taken out. A heat receiving body 29 is thermally connected to one end 24 a of the heat pipe 24, and the heat receiving body 29 is thermally connected to a heating element 52. Further, the one end 28 a of the heat pipe 28 is also thermally connected to the heat receiving body 29 and thermally connected to the heat generating body 52.

  On the other hand, the other ends 24 b and 28 b of the heat pipes 24 and 28 penetrate the plate-like fins 41 of the second radiator 40. With this cooling structure, the heat generated in the heat generating body 52 is transferred to the second heat radiating body 40 through the two heat pipes 24 and 28 and is cooled by the cooling fan 21.

  The upper closing plate 47 that covers the second heat radiating body 40 from above blocks the leakage of cooling air from above the gap 71 (see FIG. 5) between the adjacent first heat radiating bodies 42 and each plate-like shape. Cooling air leakage from above the gaps of the fins 41 is also blocked.

  FIG. 8 is a perspective view showing the cooling system related to the first heat radiator 42 taken out. A heat receiving body 27 is thermally connected to one end 26 a of the heat pipe 26, and the heat receiving body 27 is thermally connected to the heating element 51. The other end 26 b of the heat pipe 26 and the plate-like fins 43 of the first radiator 42 are penetrated. The upper closing plate 46 that covers the first radiator 42 from above blocks the leakage of cooling air from above the gap 72 (see FIG. 5) between the first radiator 42 and the side wall 8, and each plate. Cooling air leakage from above the gaps of the fins 43 is also blocked.

  FIG. 9 is a perspective view showing a state in which the cooling fan 21 and the first and second radiators 42 and 40 are removed from the perspective view of the cooling device 20 and the cooling structure shown in FIG. 6.

  A recess 11 a is formed in the bottom wall 11, and the cooling fan 21 and the first and second radiators 42 and 40 are placed in contact with the recess 11 a. For this reason, leakage from the lower side of the received cooling air 60 hardly occurs on the path from the cooling fan 21 to the ventilation hole 15.

  The shapes of the notches 37 and 38 provided in the side blocking plates 31a and 31b are slightly different from those illustrated in FIG. 5, but the effect of avoiding mechanical interference with the heat pipe is the same. .

  According to the cooling device 20 and the cooling structure for an electronic device according to the third embodiment, in addition to the effects of the second embodiment, it is possible to cool more heating elements.

(4) Other Embodiments FIG. 10 shows a form in which the cooling system related to the first heat radiator 42 is removed from the third embodiment (see FIG. 6). In an electronic device such as a personal computer, the number of heating elements that require forced cooling may differ depending on the model. For this reason, the form which can replace a cooling system easily according to the number of the heat generating bodies which require forced cooling is preferable from a viewpoint of cost reduction. For example, when there are three heating elements that require forced air cooling, the configuration shown in FIG. 6 is used, and when there are two heating elements that require forced air cooling, as shown in FIG. For example, the cooling system related to the body 42 is removed. With such a usage pattern, the cooling device 20 and components of the cooling structure can be shared, which contributes to cost reduction.

  Although the leakage of the cooled cooling air 60 slightly increases due to the new air gap generated by removing the first heat radiator 42, the presence of the side blocking plates 31a and 31b causes a cooling compared to the conventional cooling structure. Performance is improving.

  FIG. 11 is a diagram showing another embodiment according to the shape of the side blocking plate.

  The side blocking plates 32a and 32b in the form shown in FIG. 11 (a) are made longer in the direction of the cooling air passage than in the second embodiment (see FIG. 5), and the cooling fan 21 and the second heat radiation The gap 73 formed between the body 40 and the body 40 is also formed so as to be closed.

  The air gap 73 between the cooling fan 21 and the second heat radiating body 40 is not so large originally, but by closing this air gap, the recirculation of the cooled cooling air 60 to the inside of the housing 7 is further reduced. be able to.

  The upper closing plate 46 may be formed as a single upper closing plate 46 that covers the gap 71 and the gap 72 from above, as shown in FIG. Moreover, it is good also as a form which extends further and also covers the space | gap 73. FIG.

  FIG.11 (b) is a form which makes a side obstruction board a division | segmentation structure. The first side blocking plates 33a and 33b close the first gap 72 between the side wall 8 and the first radiator 42, and the second side blocking plates 34a and 34b The second gap 71 between the first radiator 42 and the first radiator 42 is closed.

  The second side blocking plates 34a and 34b are formed so as to extend from the bottom wall 11 in the vertical direction, for example, and the lower edges of the second side blocking plates 34a and 34b are connected to the bottom wall 11. Also good. The first side closing plates 33 a and 33 b may be formed so that the lower edge portion is connected to the bottom wall 11 and one side edge portion is also connected to the side wall 8.

  In this divided configuration, mechanical interference between each side blocking plate and the heat pipe can be avoided, so that notches are not necessary.

  Also in this case, the upper closing plate 46 may be formed as a single upper closing plate 46 that covers the gap 71 and the gap 72 from above, as shown in FIG. Moreover, it is good also as a form which extends further and also covers the space | gap 73. FIG.

  As described above, according to the electronic apparatus according to the present embodiment, it is possible to reduce the circulation of the received cooling air into the housing, improve the cooling efficiency, and reduce the temperature rise inside the housing. .

  Note that the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, the constituent elements over different embodiments may be appropriately combined.

1 is a perspective view showing an example of the appearance of an embodiment of an electronic apparatus according to the present invention. The top view which shows typically the cooling device and cooling structure in 1st Embodiment of the electronic device which concerns on this invention. The side view which shows typically the cooling device and cooling structure in 1st Embodiment of the electronic device which concerns on this invention. The top view which shows typically the cooling device and cooling structure in 2nd Embodiment of the electronic device which concerns on this invention. The side view which shows typically the cooling device and cooling structure in 2nd Embodiment of the electronic device which concerns on this invention. The perspective view which illustrates the cooling device and cooling structure in 3rd Embodiment of the electronic device which concerns on this invention. The perspective view which illustrates the structure of the cooling system concerning the 2nd radiator in a 3rd embodiment. The perspective view which illustrates the structure of the cooling system concerning the 1st radiator in a 3rd embodiment. The perspective view which illustrates the state which removed the cooling fan and the heat radiator in 3rd Embodiment. The perspective view which illustrates the form which removed the cooling system which concerns on a 2nd heat radiator from 3rd Embodiment. The side view which illustrates the shape which concerns on other embodiment of a side obstruction board.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electronic device 7 Housing | casing 8 Side wall 11 Bottom wall 15 Ventilation hole 20 Cooling device 21 Cooling fan 24 Heat pipe (2nd heat pipe)
26 1st heat pipe 30a, 30b, 31a, 31b, 32a, 32b, 33a, 33b Side obstruction | occlusion board 40 Radiator (2nd radiator)
41 Plate-shaped fin (fin)
42 1st radiator 43 plate-like fin (fin)
50 Heating element (second heating element)
51 First heating element 70, 71, 72

Claims (6)

A housing having a side wall provided with ventilation holes;
A heating element housed in the housing;
A radiator disposed in proximity to the vent hole;
A heat receiving member thermally connected to the heating element;
One end of which is thermally connected to the heat receiving body and the other end of which is thermally connected to the heat radiator;
A fan that is disposed in proximity to the radiator and generates cooling air toward the radiator;
A closing member configured as a separate body from a fan case for closing the gap between the heat radiating body and the side wall provided with the ventilation hole, and storing the fan;
With
The heat radiator has a plurality of plate fins, and the other end of the heat transfer means is configured to penetrate the plurality of plate fins,
The closing member is formed so as to further close a gap between the fan case that houses the fan and the heat dissipating body, two side blocking plates that close both sides of the gap, and an upper side of the gap And an upper closing plate for closing
The heat transfer member is a heat pipe, and the side block plate is provided with a notch for avoiding mechanical interference with the heat pipe,
The side block plate is connected to at least one of the bottom wall of the housing and the side wall provided with the ventilation hole, and is integrally formed in a rib structure ,
A recess is formed in the bottom wall of the housing, and the fan and the radiator are placed so as to be in contact with the recess.
An electronic device characterized by that. A housing having a side wall provided with ventilation holes;
A first heating element housed in the housing;
A second heating element housed in the housing;
A first radiator disposed in proximity to the ventilation hole;
A second radiator disposed adjacent to the first radiator;
A first heat receiving member thermally connected to the first heating element;
A second heat receiving body thermally connected to the second heating element;
A first heat pipe having one end thermally connected to the first heat receiving body and the other end thermally connected to the first heat radiating body;
A second heat pipe having one end thermally connected to the second heat receiving body and the other end thermally connected to the second heat radiating body;
A fan disposed close to the second radiator and generating cooling air toward the first and second radiators;
A first gap formed between the first heat radiator and the side wall provided with the ventilation hole, and a first gap formed between the first heat radiator and the second heat radiator. A closing plate configured to be a separate body from the fan case for storing the fan,
With
The second heat radiating body is disposed between the first heat radiating body and the fan, and the cooling air is directed from the fan toward the ventilation hole so that the second heat radiating body and the first heat radiating body are disposed. Flowing through the body in series,
The closing plate includes two side closing plates that close both sides of the first and second gaps, and an upper closing plate that closes the upper sides of the first and second gaps. ,
Each of the side blocking plates has an edge connected to at least one of the bottom wall of the housing and the side wall provided with the ventilation hole, and is integrally formed in a rib structure ,
A recess is formed in the bottom wall of the housing, and the fan and the radiator are placed so as to be in contact with the recess.
An electronic device characterized by that. Each of the first and second heat radiators includes a plurality of plate fins, and the other ends of the first and second heat pipes pass through the plurality of plate fins. The electronic apparatus according to claim 2. The electronic device according to claim 2, wherein the closing plate is formed so as to further close a gap between a fan case that houses the fan and the radiator. The electronic device according to claim 2, wherein the side blocking plate is provided with a notch for avoiding mechanical interference with the first and second heat pipes. A housing,
A first heating element housed in the housing;
A second heating element housed in the housing;
A first heat dissipating member disposed in the vicinity of the ventilation hole provided in the side wall constituting the housing;
A second radiator disposed adjacent to the first radiator;
A first heat receiving member thermally connected to the first heating element;
A second heat receiving body thermally connected to the second heating element;
A first heat pipe having one end thermally connected to the first heat receiving body and the other end thermally connected to the first heat radiating body;
A second heat pipe having one end thermally connected to the second heat receiving body and the other end thermally connected to the second heat radiating body;
A fan disposed near the second radiator and generating cooling air for exchanging heat with the first and second radiators;
A first blockade configured to block a first gap formed between the first heat radiating body and the side wall provided with the ventilation hole and separate from a fan case for storing the fan. The board,
A second closing plate configured to close a second gap formed between the first heat radiating body and the second heat radiating body and to be separated from a fan case housing the fan;
With
The first closing plate includes two first side closing plates that close both sides of the first gap, and a first upper closing plate that closes the upper side of the first gap. And
Each of the first side blocking plates has an edge connected to at least one of a bottom wall of the housing and a side wall provided with the ventilation holes, and is integrally formed in a rib structure ,
The second closing plate includes two second side closing plates that close both sides of the second gap, and a second upper closing plate that closes the upper side of the second gap. And
Each of the second side blocking plates has an edge connected to at least one of a bottom wall of the housing and a side wall provided with the ventilation holes, and is integrally formed in a rib structure ,
A recess is formed in the bottom wall of the housing, and the fan and the radiator are placed so as to be in contact with the recess.
An electronic device characterized by that.

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